CN113567704B

CN113567704B - Meteorological monitoring facilities

Info

Publication number: CN113567704B
Application number: CN202111110942.1A
Authority: CN
Inventors: 荆灿英
Original assignee: Fengyun Bowei Shenzhen Technology Co ltd
Current assignee: Fengyun Bowei Shenzhen Technology Co ltd
Priority date: 2021-09-23
Filing date: 2021-09-23
Publication date: 2021-12-07
Anticipated expiration: 2041-09-23
Also published as: CN113567704A

Abstract

The invention provides meteorological monitoring equipment, and relates to the technical field of meteorological monitoring. This meteorological monitoring equipment sets up the anemoscope at prop a tub top including propping the pipe and rotating through changeing the cover, prop the middle part of pipe and seted up the notch, be equipped with the T shape frame that comprises diaphragm and riser in the notch, be equipped with the motor on the diaphragm, the output shaft of motor upwards extends along propping a tub lumen, and be equipped with the master gear on the top of output shaft, prop the top of pipe and seted up rather than the communicating side channel of lumen, the outside cover that props the pipe is equipped with the guard shield that shelters from the side channel, install in the guard shield with master gear meshing from the gear, the symmetry is provided with two knee rods on the outer wall of guard shield. The meteorological monitoring equipment can ensure that the anemoscope cannot be frozen due to freezing when being used in winter, and can smoothly rotate.

Description

Meteorological monitoring facilities

Technical Field

The invention relates to the technical field of meteorological monitoring, in particular to meteorological monitoring equipment.

Background

The meteorological monitoring is the activity of carrying out integrity monitoring and early warning on meteorological environment conditions through a meteorological monitoring system, and the meteorological monitoring system monitors and reports indexes reflecting meteorological quality to determine meteorological environment data such as rainfall, wind speed and wind direction of the ground. General meteorological monitoring equipment includes the pole setting, and the outer fixed surface of pole setting is connected with the control box, the adjustable installation mechanism of upper end fixedly connected with of control box combines wind direction sensor and the general wind direction sensor in the market that uses on the monitoring facilities of this type of structure, and the theory of application is: the air flow in the atmosphere makes the sensor rotate, and then a wind speed signal is sent to the sensor through the rotation action of the sensor, so that the rotation action is the root of the signal source. However, when the wind direction sensor is blocked from rotating due to weather, for example, an ice layer is formed between the top of the support pipe and the rotating part of the support pipe, and the wind direction sensor is generally located at a higher position after being installed through the support pipe, the problem is not easily solved, and the normal detection of the wind speed is influenced in the same day.

Disclosure of Invention

Based on this, it is necessary to provide a meteorological monitoring device to solve the above problems.

A meteorological monitoring device comprises a supporting tube and an anemoscope rotationally arranged at the top of the supporting tube through a rotating sleeve, wherein a notch is formed in the middle of the supporting tube, a T-shaped frame composed of a transverse plate and a vertical plate is arranged in the notch, a motor is arranged on the transverse plate, an output shaft of the motor extends upwards along a tube cavity of the supporting tube, a main gear is arranged at the top end of the output shaft, a side groove communicated with the tube cavity is formed in the top end of the supporting tube, a protective cover for shielding the side groove is sleeved outside the supporting tube, a driven gear meshed with the main gear is installed in the protective cover, two bent rods are symmetrically arranged on the outer wall surface of the protective cover, an arc-shaped friction plate is arranged at the top end of each bent rod, an annular rail is arranged at the bottom end of the rotating sleeve, the two friction plates are located in the annular rail, a plurality of steel balls forming point contact with the annular rail are arranged on the inner wall surface and the top surface of each friction plate along the arc-shaped trend, and the anemoscope is driven to rotate at the top end of the supporting tube, the annular track and the steel ball generate friction action.

In one embodiment, the top surface and the outer arcuate surface of the friction plate are spaced from the bottom surface and the side wall surface of the endless track, respectively.

In one embodiment, a pier seat is arranged at the bottom end of the supporting pipe, an air speed sensor is arranged on the bottom surface of the pier seat, and the air speed sensor is electrically connected to an anemoscope.

In one embodiment, the rotating sleeve comprises an outer ring which is arranged on the outer ring of the rotating sleeve and forms point contact with the steel balls, and further comprises an inner ring which is sleeved on the top end of the supporting pipe and used for enabling the supporting pipe to rotate relative to the supporting pipe, and a sandwich-type copper ring is further fixed between the outer ring and the inner ring.

In one embodiment, the vertical plate is provided with an electricity storage device and an electrical appliance box which are electrically connected with each other, the electrical appliance box comprises a controller which is electrically connected with the wind speed sensor, the controller is also internally provided with a remote control module which is electrically connected with the motor, the notch is provided with a cover plate, and the cover plate is provided with an infrared sensing head which is electrically connected with the remote control module.

In one embodiment, a rotating rod extending into the supporting tube from the top end of the supporting tube is fixed on the bottom surface of the rotating sleeve, a generator fixed in the tube cavity of the supporting tube is connected to the bottom end of the rotating rod in a transmission manner, and the output end of the generator is electrically connected to the electricity storage device.

In one embodiment, the master gear is a missing tooth gear and the slave gears are missing tooth gears that are meshed on the master gear and mounted within the shield.

In one embodiment, the supporting tube is further provided with a bent spring, the bent spring is fixed on the opposite surface of the side groove in a welding mode, and one end of the bent spring is connected to the driven gear, so that the shield driven by the driven gear to rotate returns.

Compared with the prior art, the invention has the advantages that the supporting pipe where the anemoscope is arranged is provided with the friction plate positioned at the bottom of the supporting pipe, so that when the anemoscope rotates along with the rotating sleeve on the supporting pipe, the anemoscope can rotate more stably and the service life of the anemoscope is prolonged through the guiding of the steel balls on the friction plate, and when the anemoscope and the rotating part of the supporting pipe are blocked in rotation due to freezing phenomenon in winter, in order to solve the problem, the supporting pipe is also internally provided with the motor, the friction plate can rotate at the bottom of the rotating sleeve where the anemoscope is arranged after the motor is electrified, and the friction plate can rub the bottom surface of the rotating sleeve when rotating, so that heat generated in the friction process is transferred to the supporting pipe through the rotating sleeve, an ice layer condensed between the supporting pipe and the rotating sleeve can be melted and fall off rapidly, and therefore, the anemoscope can be ensured not to be frozen in winter, can be smoothly rotated.

Drawings

FIG. 1 is a schematic view of the overall assembly structure of the present invention;

FIG. 2 is an exploded view of the weather monitoring apparatus of the present invention, as shown in FIG. 1;

FIG. 3 is a schematic view of the side groove portion and the main gear and side groove position of the present invention;

FIG. 4 is a bottom perspective view of the weather monitoring apparatus of FIG. 1;

FIG. 5 is a schematic structural view of the shield and friction plate of the present invention and the components thereon;

fig. 6 is a schematic view of the cut-away internal structure of the electrical box of the present invention.

Detailed Description

The technical solutions of the present invention will be described in detail and fully with reference to the accompanying drawings, and it should be understood that the described embodiments are only some embodiments, but not all embodiments, of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

As shown in fig. 1 to 6, the present embodiment provides a meteorological monitoring device, which includes a supporting tube 1 and an anemoscope 2 rotatably disposed on the top of the supporting tube 1 through a rotating sleeve 3, a notch 4 is disposed in the middle of the supporting tube 1, a T-shaped frame 5 composed of a horizontal plate 6 and a vertical plate 7 is disposed in the notch 4, a motor 8 is disposed on the horizontal plate 6, an output shaft of the motor 8 extends upwards along the lumen of the supporting tube 1, a main gear 9 is disposed at the top end of the output shaft, a side groove 10 communicated with the lumen of the supporting tube 1 is disposed at the top end of the supporting tube 1, a shield 12 shielding the outside of the side groove 10 is sleeved on the outside of the supporting tube 1, a driven gear 13 engaged with the main gear 9 is disposed in the shield 12, the main gear 9 drives the shield 12 to rotate when rotating, two curved rods 14 capable of rotating synchronously with the shield 12 are symmetrically disposed on the outer wall surface of the shield 12, an arc-shaped friction plate 15 is disposed at the top end of each curved rod 14, an annular rail 16 is arranged at the bottom end of the rotating sleeve 3, the two friction plates 15 are located in the annular rail 16, a plurality of steel balls 17 in point contact with the annular rail 16 are arranged on the inner wall surface and the top surface of each friction plate 15 along the arc-shaped trend of the friction plate, and when the anemoscope 2 drives the rotating sleeve 3 to rotate at the top end of the supporting pipe 1, friction action is generated between the annular rail 16 and the steel balls 17.

The meteorological monitoring equipment is arranged on a higher detection point through a pier seat 25, when the meteorological monitoring equipment is used in winter, accumulated water possibly permeates between the top end of a supporting pipe 1 and a rotating sleeve 3 due to weather, and the meteorological monitoring equipment can be frozen after being cooled, because the rotating sleeve 3 is a rotating part and is a necessary accessory for the anemoscope 2 to rotate at the top of the supporting pipe 1, when the rotating sleeve 3 is condensed at the top end of the supporting pipe 1, the anemoscope 2 can be stopped, so that the anemoscope 2 can not feed back data to an anemoscope 26 within a certain period of time, the mode is the prior art, the anemoscope 26 and the anemoscope 2 are generally called as an anemoscope detection device in actual use, the principle of the invention is not detailed any more, if the phenomenon happens, a motor 8 is electrified, the anemoscope drives a main gear 9 to rotate through a rotating shaft, and the main gear 9 can also be meshed with a slave gear 13 to rotate when rotating, and because the main gear 9 is a gear with missing teeth, and the secondary gear 13 is a gear with missing teeth which is engaged on the main gear 9 and is arranged in the shield 12, when the main gear 9 rotates to be engaged with a gear with missing teeth part on the secondary gear 13, the secondary gear 13 is driven to rotate for an angle, so that the shield 12 rotates along with the same angle, finally the shield 12 carries the friction plate 15 and the annular track 16 through the bent rod 14 according to the rotation rule to carry out high-frequency friction through the steel balls 17, so that the steel balls 17 and the annular track 16 generate heat, the generated heat is transferred to the rotating sleeve 3, and the ice layer condensed between the rotating sleeve 3 and the supporting pipe 1 is melted, and the rotating sleeve 3 can rotate with the anemoscope 2 at the moment, so that the anemoscope 2 is recovered to a normal use state.

As shown in fig. 4, the top surface and the outer arc surface of the friction plate 15 are respectively spaced from the bottom surface and the side wall surface of the annular track 16, and the contact manner between the steel balls 17 on the friction plate 15 and the rotating sleeve 3 is point contact, so the rotating sleeve 3 and the steel balls 17 are equivalent to a ball bearing, therefore, even if the friction plate 15 is arranged, when the anemoscope 2 rotates under the action of air flow in wind weather, the anemoscope 2 is not blocked due to the frictional contact with the friction plate 15, and when the ice layer between the rotating sleeve 3 and the support tube 1 needs to be melted through the above manner, the above embodiment can enable the anemoscope 2 to rotate smoothly, so the structural design is ingenious and reasonable, and in order to further improve the structural reasonableness, as shown in fig. 2 and 4, the rotating sleeve 3 comprises an outer ring 18 which is arranged on the outer ring and forms point contact with the steel balls 17, and further comprises an inner ring 19 which is sleeved on the top end of the support tube 1 and is used for enabling the support tube 1 to rotate relatively, a sandwich-type copper ring 20 is further fixed between the outer ring 18 and the inner ring 19, and the copper ring 20 has high thermal conductivity, so that heat generated by friction in the above manner can be rapidly transferred to the rotary sleeve 3 through the copper ring 20.

As shown in fig. 2, fig. 3 and fig. 6, the vertical plate 7 is provided with an electric storage device 21 and an electric appliance box 22 which are electrically connected with each other, the electric appliance box 22 includes a controller 27 electrically connected to the wind speed sensor 26, the controller 27 is further provided with a remote control module 28 electrically connected to the motor 8, the notch 4 is provided with a cover plate 29, the cover plate 29 is provided with an infrared sensing head 31 electrically connected to the remote control module 28, in practical use, the ground remote controller is matched with the electric appliance, and the infrared sensing head 31 sends an instruction to the remote control module 28, so that the motor 8 completes the rotation under remote control, and the purpose of remote control is achieved.

As shown in fig. 2 and 3, a rotating rod 23 extending into the supporting tube 1 from the top end of the supporting tube 1 is fixed on the bottom surface of the rotating sleeve 3, a generator 24 fixed in the tube cavity of the supporting tube 1 is connected to the bottom end of the rotating rod 23 in a transmission manner, and the output end of the generator 24 is electrically connected to the electricity storage device 21, i.e., when in actual use, the rotating sleeve 3 is driven to rotate by airflow in the atmosphere through the anemoscope 2, and the rotating sleeve 3 also drives the generator 24 to rotate at high frequency through the rotating rod 23, according to the existing power generation principle of the generator, wind energy is converted into electric energy to continuously supply power to the electricity storage device 21, and the obtained power is just used for supplying power to the electrical components related to the meteorological monitoring equipment, so as to achieve the purpose of energy conservation and electricity utilization.

As shown in fig. 5, the stay 1 is further provided with a bending spring 30, the bending spring 30 is fixed to the opposite surface of the side groove 10 by welding, and one end of the bending spring 30 is connected to the slave gear 13 so as to return the shield 12 rotated by the slave gear 13 again, and when the master gear 9 is rotated again to the slave gear 13, the shield 12 is rotated again by meshing with the slave gear 13, and when the master gear 9 is separated from the slave gear 13, the slave gear 13 is returned again by the influence of the tensile force of the bending spring 30, and finally the shield 12 is rotated at a high frequency in conjunction with the friction plate 15.

The above embodiments further describe the object, technical means, and advantageous effects of the present invention in detail. It should be understood that the above are only specific embodiments of the present invention, and are not intended to limit the scope of the present invention. It should be understood that any modifications, equivalents, improvements and the like, which come within the spirit and principle of the invention, may occur to those skilled in the art and are intended to be included within the scope of the invention.

Claims

1. The utility model provides a meteorological monitoring equipment, includes prop pipe (1) and rotationally sets up anemograph (2) at prop pipe (1) top through changeing cover (3), its characterized in that: a notch (4) is formed in the middle of the supporting tube (1), a T-shaped frame (5) consisting of a transverse plate (6) and a vertical plate (7) is arranged in the notch (4), a motor (8) is arranged on the transverse plate (6), an output shaft of the motor (8) extends upwards along the tube cavity of the supporting tube (1), a main gear (9) is arranged at the top end of the output shaft, a side groove (10) communicated with the tube cavity is formed in the top end of the supporting tube (1), a protective cover (12) for shielding the side groove (10) is sleeved on the outer side of the supporting tube (1), a driven gear (13) meshed with the main gear (9) is arranged in the protective cover (12), two bent rods (14) are symmetrically arranged on the outer wall surface of the protective cover (12), an arc-shaped friction plate (15) is arranged at the top end of each bent rod (14), an annular rail (16) is formed in the bottom end of the rotating sleeve (3), and the two friction plates (15) are both positioned in the annular rail (16), a plurality of steel balls (17) which are in point contact with the annular rail (16) are arranged on the inner wall surface and the top surface of the friction plate (15) along the arc-shaped trend, and when the anemoscope (2) drives the rotating sleeve (3) to rotate at the top end of the supporting pipe (1), the annular rail (16) and the steel balls (17) generate friction action;

gaps are reserved between the top surface and the outer arc surface of the friction plate (15) and the bottom surface and the side wall surface of the annular track (16) respectively;

a pier seat (25) is arranged at the bottom end of the supporting pipe (1), an air speed sensor (26) is arranged on the bottom surface of the pier seat (25), and the air speed sensor (26) is electrically connected with the anemoscope (2);

the rotating sleeve (3) comprises an outer ring (18) which is arranged on the outer ring of the rotating sleeve and forms point contact with the steel balls (17), and also comprises an inner ring (19) which is sleeved on the top end of the supporting pipe (1) and can rotate relative to the supporting pipe (1), and a sandwich-type copper ring (20) is also fixed between the outer ring (18) and the inner ring (19);

an electric storage device (21) and an electric appliance box (22) which are electrically connected with each other are arranged on the vertical plate (7), a controller (27) which is electrically connected with the wind speed sensor (26) is arranged in the electric appliance box (22), a remote control module (28) which is electrically connected with the motor (8) is also arranged in the controller (27), a cover plate (29) is arranged on the notch (4), and an infrared sensing head (31) which is electrically connected with the remote control module (28) is arranged on the cover plate (29);

a rotating rod (23) extending from the top end of the supporting tube (1) into the supporting tube (1) is fixed on the bottom surface of the rotating sleeve (3), a generator (24) fixed in the tube cavity of the supporting tube (1) is connected to the bottom end of the rotating rod (23) in a transmission manner, and the output end of the generator (24) is electrically connected to the electricity storage device (21);

the main gear (9) is a gear with missing teeth, and the secondary gear (13) is a gear with missing teeth which is meshed on the main gear (9) and is arranged in the shield (12);

the supporting tube (1) is also provided with a bent spring (30), the bent spring (30) is fixed on the opposite surface of the side groove (10) in a welding mode, and one end of the bent spring (30) is connected to the driven gear (13) so as to enable the driven gear (13) to drive the rotated shield (12) to return.